Identification of a Region of the Herpes Simplex Virus Single-Stranded DNA-Binding Protein Involved in Cooperative Binding

We have identified a region of the herpes simplex virus major DNA-binding protein (ICP8) which is involved in cooperative binding to single-stranded DNA. This has been accomplished by analysis of ICP8 which was covalently modified by reaction with the extrinsic fluorophore fluorescein-5-maleimide (FM). Reaction conditions which result in the incorporation of 1 mol of FM per mol of ICP8 have been established. The binding properties of the modified protein were analyzed by polyacrylamide gel shift analysis with model oligonucleotides. This analysis indicates that while intrinsic binding is similar to that observed with unmodified protein, the cooperative binding of the modified protein to single-stranded DNA is significantly altered. Helix-destabilizing assays, whose results are a reflection of cooperative binding, also indicate that this property of ICP8 is decreased upon modification with FM. Mapping of the site of modification by cyanogen bromide cleavage and peptide sequencing has shown that the major site of modification is cysteine 254. This position in the primary structure of ICP8 is distinct from the regions previously shown to be involved in the interaction of this protein with single-stranded DNA.     

N-ethylmaleimide inhibition of the DNA-binding activity of the herpes simplex virus type 1 major DNA-binding protein.

The major herpes simplex virus DNA-binding protein, designated ICP8, binds tightly to single-stranded DNA and is required for replication of viral DNA. The sensitivity of the DNA-binding activity of ICP8 to the action of the sulfhydryl reagent N-ethylmaleimide has been examined by using nitrocellulose filter-binding and agarose gel electrophoresis assays. Incubation of ICP8 with N-ethylmaleimide results in a rapid loss of DNA-binding activity. Preincubation of ICP8 with single-stranded DNA markedly inhibits this loss of binding activity. These results imply that a free sulfhydryl group is involved in the interaction of ICP8 with single-stranded DNA and that this sulfhydryl group becomes less accessible to the environment upon binding. Agarose gel electrophoretic analysis of the binding interaction in the presence and absence of N-ethylmaleimide indicates that the cooperative binding exhibited by ICP8 is lost upon treatment with this reagent but that some residual noncooperative binding may remain. This last result was confirmed by equilibrium dialysis experiments with the 32P-labeled oligonucleotide dT10 and native and N-ethylmaleimide-treated ICP8.     

Ligand induced stabilization of the melting temperature of the HSV-1 single-strand DNA binding protein using the thermal shift assay

We have adapted the thermal shift assay to measure the ligand binding properties of the herpes simplex virus-1 single-strand DNA binding protein, ICP8. By measuring SYPRO Orange fluorescence in microtiter plates using a fluorescence-enabled thermal cycler, we have quantified the effects of oligonucleotide ligands on the melting temperature of ICP8. We found that single-stranded oligomers raise the melting temperature of ICP8 in a length- and concentration-dependent manner, ranging from 1 °C for (dT)₅ to a maximum of 9 °C with oligomers ?10 nucleotides, with an apparent K_d of <1 μM for (dT)₂₀. Specifically, the results indicate that ICP8 is capable of interacting with oligomers as short as 5 nucleotides. Moreover, the observed increases in melting temperature of up to 9 °C, indicates that single-strand DNA binding significantly stabilizes the structure of ICP8. This assay may be applied to investigate the ligand binding proteins of other single-strand DNA binding proteins and used as a high-throughput screen to identify compounds with therapeutic potential that inhibit single-strand DNA binding. As proof of concept, the single-strand DNA binding agent ciprofloxacin reduces the ligand induced stabilization of the melting temperature of ICP8 in a dose-dependent manner.     

Recognition and cleavage of hairpin structures in nucleic acids by oligodeoxynucleotides.

The possibility of designing antisense oligodeoxynucleotides complementary to non-adjacent single-stranded sequences containing hairpin structures was studied using a DNA model system. The structure and stability of complexes formed by a 17mer oligonucleotide with DNA fragments containing hairpin structures was investigated by spectroscopic measurements (melting curves) and chemical reactions (osmium tetroxide reaction, copper-phenanthroline cleavage). A three-way junction was formed when the oligonucleotide was bound to both sides of the hairpin structure. When the complementary sequences of the two parts of the oligonucleotide were separated by a sequence which could not form a hairpin, the oligonucleotide exhibited a slightly weaker binding than to the hairpin-containing target. An oligodeoxynucleotide-phenanthroline conjugate was designed to form Watson-Crick base pairs with two single-stranded regions flanking a hairpin structure in a DNA fragment. In the presence of Cu2+ ions and a reducing agent, two main cleavage sites were observed at the end of the duplex structure formed by the oligonucleotide-phenanthroline conjugate with its target sequence. Competition experiments showed that both parts of the oligonucleotide must be bound in order to observe sequence-specific cleavage. Cleavage was still observed with target sequences which could not form a hairpin, provided the reaction was carried out at lower temperatures. These results show that sequence-specific recognition and modification (cleavage) can be achieved with antisense oligonucleotides which bind to non-adjacent sequences in a single-stranded nucleic acid.     

Surface lysine and tyrosine residues are required for interaction of the major herpes simplex virus type 1 DNA-binding protein with single-stranded DNA.

Modification of the herpes simplex virus type 1 major DNA-binding protein (ICP8) with reagents and conditions specific for arginine, lysine, and tyrosine residues indicates that surface lysine and tyrosine residues are required for the interaction of this protein with single-stranded DNA. Modification of either of these two amino acids resulted in a loss and/or modification of binding activity as judged by nitrocellulose filter assays and gel shift. Modification specific for arginine residues did not affect binding within the limits of the assays used. Finally, quenching of the intrinsic tryptophan fluorescence of ICP8 in the presence of single-stranded DNA either suggests involvement of this amino acid in the binding reaction or reflects a conformational change in the protein upon binding.     

Equilibrium binding of single-stranded DNA with herpes simplex virus type I-coded single-stranded DNA-binding protein, ICP8

We have carried out solution equilibrium binding studies of ICP8, the major single-stranded DNA (ssDNA)-binding protein of herpes simplex virus type I, in order to determine the thermodynamic parameters for its interaction with ssDNA. Fluorescence anisotropy measurements of a 5'-fluorescein-labeled 32-mer oligonucleotide revealed that ICP8 formed a nucleoprotein filament on ssDNA with a binding site size of 10 nucleotides/ICP8 monomer, an association constant at 25 degrees C, K = 0.55 +/- 0.05 x 10(6) M(-1), and a cooperativity parameter, omega = 15 +/- 3. The equilibrium constant was largely independent of salt, deltalog(Komega)/deltalog([NaCl]) = -2.4 +/- 0.4. Comparison of these parameters with other ssDNA-binding proteins showed that ICP8 reacted with an unusual mechanism characterized by low cooperativity and weak binding. In addition, the reaction product was more stable at high salt concentrations, and fluorescence enhancement of etheno-ssDNA by ICP8 was higher than for other ssDNA-binding proteins. These last two characteristics are also found for protein-DNA complexes formed by recombinases in their active conformation. Given the proposed role of ICP8 in promoting strand transfer reactions, they suggest that ICP8 and recombinase proteins may catalyze homologous recombination by a similar mechanism.     

Interaction between the DNA polymerase and single-stranded DNA-binding protein (infected cell protein 8) of herpes simplex virus 1

The herpes virus-encoded DNA replication protein, infected cell protein 8 (ICP8), binds specifically to single-stranded DNA with a stoichiometry of one ICP8 molecule/12 nucleotides. In the absence of single-stranded DNA, it assembles into long filamentous structures. Binding of ICP8 inhibits DNA synthesis by the herpes-induced DNA polymerase on singly primed single-stranded DNA circles. In contrast, ICP8 greatly stimulates replication of circular duplex DNA by the polymerase. Stimulation occurs only in the presence of a nuclear extract from herpes-infected cells. Appearance of the stimulatory activity in nuclear extracts coincides closely with the time of appearance of herpes-induced DNA replication proteins including ICP8 and DNA polymerase. A viral factor(s) may therefore be required to mediate ICP8 function in DNA replication.     

In vitro characterization of a thermolabile herpes simplex virus DNA-binding protein.

The major herpes simplex virus DNA-binding protein, ICP8, was purified from cells infected with the herpes simplex virus type 1 temperature-sensitive strain tsHA1. tsHA1 ICP8 bound single-stranded DNA in filter binding assays carried out at room temperature and exhibited nonrandom binding to single-stranded bacteriophage fd DNA circles as determined by electron microscopy. The filter binding assay results and the apparent nucleotide spacing of the DNA complexed with protein were identical, within experimental error, to those observed with wild-type ICP8. Thermal inactivation assays, however, showed that the DNA-binding activity of tsHA1 ICP8 was 50% inactivated at approximately 39 degrees C as compared with 45 degrees C for the wild-type protein. Both wild-type and tsHA1 ICP8 were capable of stimulating viral DNA polymerase activity at permissive temperatures. The stimulatory effect of both proteins was lost at 39 degrees C.     

Herpes simplex virus type 1 single-strand DNA binding protein ICP8 enhances the nuclease activity of the UL12 alkaline nuclease by increasing its processivity

UL12 is a 5'- to 3'-exonuclease encoded by herpes simplex virus type 1 (HSV-1) which degrades single- and double-stranded DNA. UL12 and the single-strand DNA binding protein ICP8 mediate a strand exchange reaction. We found that ICP8 inhibited UL12 digestion of single-stranded DNA but stimulated digestion of double-stranded DNA threefold. The stimulatory effect of ICP8 was independent of a strand exchange reaction; furthermore, the effect was specific to ICP8, as it could not be reproduced by Escherichia coli single-stranded DNA binding protein. The effect of ICP8 on the rate of UL12 double-stranded DNA digestion is attributable to an increase in processivity in the presence of ICP8.     

Investigation of RecA--polynucleotide interactions from the measurement of LexA repressor cleavage kinetics. Presence of different types of complex

The proteolysis of the LexA repressor in the presence of RecA and various polynucleotides was studied by measuring the fluorescence decrease of LexA upon cleavage. The results were compared with the DNA binding of RecA to investigate the presence of multiple DNA-RecA complexes. All single-stranded polydeoxyribonucleotides (DNA) efficiently stimulated the proteolysis and the maximum activation was reached in the presence of three or four nucleotides of polynucleotide per monomer of RecA. The stimulative effect was decreased in the presence of larger amounts of poly(dA), poly(dT) or heat-denatured DNA, whereas the excess of single-stranded DNAs chemically modified with chloroacetaldehyde did not present such an inhibitory effect, despite the fact that a second DNA molecule is likely to interact with RecA as monitored by the intrinsic fluorescence of these DNA species. The complicated cleavage promotion and inhibition pattern is tentatively explained by a three-state model assuming that RecA may interact with three single-stranded DNA molecules. According to this model, occupation of the first site would be necessary and sufficient for cleavage promotion, the second site would be neutral with respect to cleavage and the occupation of the third site would inhibit LexA cleavage at least partially. Double-stranded natural DNA did not stimulate cleavage, even under conditions where RecA binds quantitatively to the DNA. No polyribonucleotides (RNA) examined showed a significant stimulative effect either, nor did they appear to interact with RecA.     

R150A mutant of F TraI relaxase domain: reduced affinity and specificity for single-stranded DNA and altered fluorescence anisotropy of a bound labeled oligonucleotide

F factor TraI is a helicase and a single-stranded DNA nuclease ("relaxase") essential for conjugative DNA transfer. A TraI domain containing relaxase activity, TraI36, was generated previously. Substituting Ala for Arg150 (R150A) of TraI36 reduces in vitro relaxase activity. The mutant has reduced affinity, relative to wild type, for a 3'-TAMRA-labeled 22-base single-stranded oligonucleotide. While both R150A and wild-type TraI36 bind oligonucleotide, only wild type increases steady-state fluorescence anisotropy of the labeled 22-base oligonucleotide upon binding. In contrast, binding by either protein increases steady-state anisotropy of a 3'-TAMRA-labeled 17-base oligonucleotide. Time-resolved intensity data for both oligonucleotides, bound and unbound, require three lifetimes for adequate fits, at least one more than the fluorophore alone. The preexponential amplitude for the longest lifetime increases upon binding. Time-resolved anisotropy data for both oligonucleotides, bound and unbound, require two rotational correlation times for adequate fits. The longer correlation time increases upon protein binding. Correlation times for the protein-bound 17-base oligonucleotide are similar for both proteins, with the longer correlation time in the range of molecular tumbling of the protein-DNA complex. In contrast, protein binding causes less dramatic increases in correlation times for the 22-base oligonucleotide relative to the 17-base oligonucleotide. Binding studies indicate that R150 contributes to recognition of bases immediately 3' to the DNA cleavage site, consistent with the apparent proximity of R150 and the 3' oligonucleotide end. Models in which the R150A substitution alters single-stranded DNA flexibility at the oligonucleotide 3' end or affects fluorophore-DNA or fluorophore-protein interactions are discussed.     

Complex of the herpes simplex virus type 1 origin binding protein UL9 with DNA as a platform for the design of a new type of antiviral drugs

The herpes simplex virus type 1 origin-binding protein, OBP, is a DNA helicase encoded by the UL9 gene. The protein binds in a sequence-specific manner to the viral origins of replication, two OriS sites and one OriL site. In order to search for efficient inhibitors of the OBP activity, we have obtained a recombinant origin-binding protein expressed in Escherichia coli cells. The UL9 gene has been amplified by PCR and inserted into a modified plasmid pET14 between NdeI and KpnI sites. The recombinant protein binds to Box I and Box II sequences and possesses helicase and ATPase activities. In the presence of ATP and viral protein ICP8 (single-strand DNA-binding protein), the initiator protein induces unwinding of the minimal OriS duplex (≈80?bp). The protein also binds to a single-stranded DNA (OriS^?) containing a stable Box I-Box III hairpin and an unstable AT-rich hairpin at the 3′-end. In the present work, new minor groove binding ligands have been synthesized which are capable to inhibit the development of virus-induced cytopathic effect in cultured Vero cells. Studies on binding of these compounds to DNA and synthetic oligonucleotides have been performed by fluorescence methods, gel mobility shift analysis and footprinting assays. Footprinting studies have revealed that Pt-bis-netropsin and related molecules exhibit preferences for binding to the AT-spacer in OriS. The drugs stabilize structure of the AT-rich region and inhibit the fluctuation opening of AT-base pairs which is a prerequisite to unwinding of DNA by OBP. Kinetics of ATP-dependent unwinding of OriS in the presence and absence of netropsin derivatives have been studied by measuring the efficiency of Forster resonance energy transfer (FRET) between fluorophores attached to 5′- and 3′- ends of an oligonucleotide in the minimal OriS duplex. The results are consistent with the suggestion that OBP is the DNA Holiday junction (HJ) binding helicase. The protein induces conformation changes (bending and partial melting) of OriS duplexes and stimulates HJ formation in the absence of ATP. The antiviral activity of bis-netropsins is coupled with their ability to inhibit the fluctuation opening of АТ base pairs in the А?+?Т cluster and their capacity to stabilize the structure of the АТ-rich hairpin in the single-stranded oligonucleotide corresponding to the upper chain in the minimal duplex OriS. The antiviral activities of bis-netropsins in cell culture and their therapeutic effects on HSV1-infected laboratory animals have been studied.     

The 60-residue C-terminal region of the single-stranded DNA binding protein of herpes simplex virus type 1 is required for cooperative DNA binding

ICP8 is the major single-stranded DNA (ssDNA) binding protein of the herpes simplex virus type 1 and is required for the onset and maintenance of viral genomic replication. To identify regions responsible for the cooperative binding to ssDNA, several mutants of ICP8 have been characterized. Total reflection X-ray fluorescence experiments on the constructs confirmed the presence of one zinc atom per molecule. Comparative analysis of the mutants by electrophoretic mobility shift assays was done with oligonucleotides for which the number of bases is approximately that occluded by one protein molecule. The analysis indicated that neither removal of the 60-amino-acid C-terminal region nor Cys254Ser and Cys455Ser mutations qualitatively affect the intrinsic DNA binding ability of ICP8. The C-terminal deletion mutants, however, exhibit a total loss of cooperativity on longer ssDNA stretches. This behavior is only slightly modulated by the two-cysteine substitution. Circular dichroism experiments suggest a role for this C-terminal tail in protein stabilization as well as in intermolecular interactions. The results show that the cooperative nature of the ssDNA binding of ICP8 is localized in the 60-residue C-terminal region. Since the anchoring of a C- or N-terminal arm of one protein onto the adjacent one on the DNA strand has been reported for other ssDNA binding proteins, this appears to be the general structural mechanism responsible for the cooperative ssDNA binding by this class of protein.     

Specific oligonucleotide invasion into an end of a DNA duplex

A new phenomenon was described: a double-stranded DNA fragment interacted with a single-stranded oligonucleotide complementary to the terminal region of one strand of the duplex to yield a complex with oligonucleotide invasion. Generation of Holliday junctions by homologous linear DNA fragments was less efficient in the presence of single-stranded oligonucleotides complementary to duplex ends. The effect depended on the oligonucleotide concentration, size, and complementarity to a duplex strand. Sequence-specific complexes with single strand invasion were detected in mixtures containing radiolabeled oligonucleotides and duplexes. A single-stranded oligonucleotide invaded a duplex even when its concentration was far lower than the duplex concentration. Complexes with single strand invasion were analyzed by chemical cleavage of noncanonical base pairs. Analysis showed that an oligonucleotide interacts with the complementary region of one strand of the duplex, gradually displacing the other strand. The extent of oligonucleotide invasion into the duplex considerably varied. Oligonucleotide invasion into duplexes became more efficient with increasing oligonucleotide size.     

Absorption and fluorescence studies of the binding of the recA gene product from E. coli to single-stranded and double-stranded DNA. Ionic strength dependence

The binding of the recA gene product from E. coli to double-stranded and single-stranded nucleic acids has been investigated by following the change in melting temperature of duplex DNA and the fluorescence of single-stranded DNA or poly(dA) modified by reaction with chloroacetaldehyde. At low ionic strength, in the absence of Mg2+ ions, RecA protein binds preferentially to duplex DNA or poly(dA-dT). This leads to an increase of the DNA melting temperature. Stabilization of duplex DNA decreases when ionic strength or pH increases. In the presence of Mg2+ ions, preferential binding to single-stranded polynucleotides is observed. Precipitation occurs when duplex DNA begins to melt in the presence of RecA protein. From competition experiments, different single-stranded and double-stranded polydeoxynucleotides can be ranked according to their ability to bind RecA protein. Structural changes induced in nucleic acids upon RecA binding are discussed together with conformational changes induced in RecA protein upon magnesium binding.     

Thermodynamic analysis of the single-stranded DNA binding activity of the archaeal replication protein A (RPA) from Sulfolobus solfataricus

The single-stranded DNA binding protein from Sulfolobus solfataricus (Sso-RPA) binds single-stranded DNA with dissociation constants in the range of 10-30 nM at room temperature. The affinity for DNA decreases at higher temperatures. At 85 degrees C, the optimal growth temperature of the crenarchaeot S. solfataricus, the dissociation constant is only about 1 microM. We analyzed the equilibrium between Sso-RPA and a fluorescently labeled 13 nucleotide oligonucleotide by fluorescence anisotropy measurements in the presence of four different salts and in the temperature range between 10 and 60 degrees C. In the presence of potassium chloride and choline chloride, three to four ions are released upon complexation, independent of the temperature. In contrast, in the presence of potassium fluoride and potassium glutamate, we observed a significant change of the number of ions released when the temperature was varied. The binding reaction is strongly exothermic with enthalpies of about -55 to -70 kJ/mol, depending upon the salt. Van't Hoff analysis suggests that the binding enthalpy is temperature independent.     

A cytomegalovirus protein with properties of herpes simplex virus ICP8: partial purification of the polypeptide and map position of the gene.

We demonstrated the presence of a single-stranded DNA-binding protein in human cytomegalovirus (CMV)-infected cells with properties analogous to those of herpes simplex virus (HSV) ICP8. Using monoclonal antibody specific for the CMV protein, we analyzed its fluorescence pattern and time of synthesis, mapped the gene encoding it by using a lambda gt11 library of CMV DNA fragments, and monitored its purification by phosphocellulose and DNA-Sepharose chromatography. In all characteristics we examined, the CMV protein behaved analogously to HSV ICP8. Our results are consistent with a functional role of CMV ICP8 in viral replication that is similar to that of HSV ICP8 and with the evolutionary conservation of the gene of interest in two divergent herpesviruses.     

Identification of a divalent metal cation binding site in herpes simplex virus 1 (HSV-1) ICP8 required for HSV replication

Herpes simplex virus 1 (HSV-1) ICP8 is a single-stranded DNA-binding protein that is necessary for viral DNA replication and exhibits recombinase activity in vitro. Alignment of the HSV-1 ICP8 amino acid sequence with ICP8 homologs from other herpesviruses revealed conserved aspartic acid (D) and glutamic acid (E) residues. Amino acid residue D1087 was conserved in every ICP8 homolog analyzed, indicating that it is likely critical for ICP8 function. We took a genetic approach to investigate the functions of the conserved ICP8 D and E residues in HSV-1 replication. The E1086A D1087A mutant form of ICP8 failed to support the replication of an ICP8 mutant virus in a complementation assay. E1086A D1087A mutant ICP8 bound DNA, albeit with reduced affinity, demonstrating that the protein is not globally misfolded. This mutant form of ICP8 was also recognized by a conformation-specific antibody, further indicating that its overall structure was intact. A recombinant virus expressing E1086A D1087A mutant ICP8 was defective in viral replication, viral DNA synthesis, and late gene expression in Vero cells. A class of enzymes called DDE recombinases utilize conserved D and E residues to coordinate divalent metal cations in their active sites. We investigated whether the conserved D and E residues in ICP8 were also required for binding metal cations and found that the E1086A D1087A mutant form of ICP8 exhibited altered divalent metal binding in an in vitro iron-induced cleavage assay. These results identify a novel divalent metal cation-binding site in ICP8 that is required for ICP8 functions during viral replication.     

Structural features of the single-stranded DNA-binding protein of Epstein-Barr virus

We report the structural features of a C-terminal deletion construct of the Epstein-Barr virus single-stranded DNA-binding protein, Balf2 (Balf2DeltaC), which like the herpes simplex virus I encoded protein, infected cell protein 8 (ICP8), binds non-sequence specifically to single-stranded DNA (ssDNA). ICP8, in the absence of ssDNA, assembles into long filamentous structures. Removal of the 60 C-terminal amino acids of ICP8 (ICP8DeltaC) prevents the formation of such filaments, whereas addition of circular ssDNA to ICP8DeltaC induces formation of "super helical" filaments. Balf2DeltaC, which we show is a zinc-binding protein, does not form these filaments under the same conditions but does bind ssDNA in a weakly cooperative manner. Further structural comparison of both proteins in solution by small-angle X-ray scattering shows proteins with similar molecular envelopes. One major difference is the tendency of Balf2DeltaC to dimerize on different surfaces to that used for oligomerization when binding to ssDNA, and this may have implications for the mechanism of replication initiation.     

Interaction with nucleic acids and stimulation of the viral DNA polymerase by the herpes simplex virus type 1 major DNA-binding protein

The interaction of the herpes simplex virus type 1 (HSV-1) major DNA-binding protein, infected-cell polypeptide 8 (ICP8), with nucleic acids has been examined by a filter-binding assay and electron microscopy. Filter-binding assays done over a broad pH range indicated that the optimum pH for the protein-DNA interaction is approximately 7.6. Heat inactivation studies showed that ICP8 is stable at temperatures up to 40 degrees C with a rapid loss of binding activity on incubation at 45 degrees C and above. Competition binding experiments have established the following relative affinities of ICP8 for the following nucleic acids: single-stranded HSV-1 DNA congruent to bacteriophage fd DNA greater than polyriboadenylate much greater than double-stranded HSV-1 DNA congruent to d(pCpT)5. Observation of negatively stained ICP8-single-stranded DNA complexes indicated that ICP8 binds along the length of the DNA in a regular repeating fashion. The average width of these complexes is 9.3 +/- 0.8 nms. Finally. Finally, addition of purified ICP8 to HSV-1 DNA polymerase reactions resulted in a stimulation of the viral polymerase activity.